Process for preparing quick-cooking barley



Uni

Patented July 12, 1960 PRGCESS FOR PREPARING QUICK-COOKING BARLEY Edward Seltzer, Teaneek, N.J., assignor to Thomas J.

Lipton, inc, Hohoken, N.J., a corporation of Delaware No Drawing. Original application Sept. 30, 1953, Ser. .No. 333,405. Divided and this application Nov. 17, 1958, Ser. No. 774,148

4 Claims. (Cl. 99-80) This invention relates to processed starch-containing products such as rice and barley, and to methods of production thereof. More particularly this invention relates to quick-cooking barley, which can be prepared for the table in a relatively short period of time compared to that normally necessary for such raw milled grains, and, a method of manufacture thereof which conditions the product for easy and quick home preparation as a food item, either alone or when the product is part of a dry packaged mix, such as a mix for soup or the like.

This is a division of my application Serial No. 383,405, filed September 30, 1953, now US. Patent No. 2,890,957,

dated June 16, 1959.

Normallyobtainable raw polished rice generally has dense, hard grains consisting largely of raw starch. and having a moisture content ranging from 8% to 14%. Such rice usually requires at least twenty minutes to cook to a suitable palatability in boiling water, or in soup or the like. When cooked alone it is accepted practice to rinse, then 'boil the rice in an excess of water, then to drain off the cooking water in a sieve or the like, and to wash the rice with a relatively large amount of hot or cold water. Such cooking will generally produce a hydrated rice containing from 70% to 80% moisture depending upon the particular conditions of cooking. This procedure has generally been considered somewhat unsatisfactory by many because of the time and care necessary, and because of the relative difficulty in producing a final product which has uniformly high quality and attractiveness. Furthermore, some people contend that the long boiling in water, which tends to burst some of the grains, and the rinsing remove a substantial amount of the valuable constituents (other than starch), i.e., minerals, vitamins and natural sugars.

Various attempts havebeen made to factory-process rice to reduce the time necessary in the home preparation, resulting in the so-called quickcooking rices.

With the presently available quick-cooking rices it has.

been found that the home-reconstituted product may become extremely friable. Consequently products of this type must be spooned very gently when prepared in the kitchen to prevent excessive breakage which tends to produce an unattractive mass rather than the attractive individual grains generally considered desirable. In addition it has been found that such products are very sensitive to over-cooking, and when vigorously boiled in a Water suspension such as in soups for more than the minimum period of time, the grains tend to split and break or fray at the ends so as to form a starchy mass. A further difiiculty with quick-cooking rices of the types generally available for use in prepared mixes is that their moisture content range is too high, i.e., from 10% to 14% moisture. The reason for their unacceptability is that each of the ingredients in a dry packaged mix must not have more than a predetermined moisture content; otherwise, there may be a transfer of moisture from one ingredient to another which may then deteriorate when at the higher moisture content. Accordingly, if such rice is to be used in many packaged mixes, its moisture content must be reduced to about 5% to 6.5%. In the drying of certain other quick-cooking rices to a low moisture content, it has been found that the wholeness of the grains is affected so that the individual rice grains tend to disintegrate upon cooking. Some methods of processing rice as discussed above also result in substantial losses to the boiling and rinsing water because of the progressive disintegration of the grains and the leaching out and dissolving of constituents.

The preparation of starch-containing products such as barley for the table involves cooking processes consuming even greater periods of time than does rice. Raw pearl barley is customarily soaked for a long period of time, as much as 7 to 12 hours, depending upon the size of grain, and then boiled for a period of three-quarters of an hour to an hour; or, it is boiled for a longer period without prior soaking. If soaking is practiced, the soaking water must be discarded because it has objectionable flavorings and colorings; i.e., it is bitter and grey or pink. If there is no soaking of the barley, the cooking water has a heavy branny flavor which can dominate the flavors of dishes, such as soups, stews, puddings, etc. These characteristics of long preparation time and strong -flavor' dominance have limited the usefulness of barley as an ingredient in prepared soup mixes and other dishes and as a food alone. Problems such as those discussed above are present with respect to other cereals and other starch products. v

Accordingly it is an object of the present invention to produce dry quick-cooking barley, which can be prepared for consumption quickly and which is without limitation as to its usefulness for dry packaged mixes. 'It is an,

other object to provide such quick-cooking products having improved properties of grain separateness and wholeness on cooking for the table. It is another object to provide a pre-cooked cereal in which the grains are non-friable so that loss due to breakage is diminished. It is another object of the present invention to provide such products having improved and uniform attractiveness when cooked for eating. It is a further object to provide. products in which the individual grains are resistant. to fraying, splitting and breaking during the hydration and final cooking. It is a still further object to provide dry quick-cooking barley in which gentle-- ness of mixing orstirringupon reconstitution is not overly critical. Another object is to provide products such as the above which may be prepared in a period often minutes which is considered a .sutiable maximum time for cooking soup mixes. It is another object to provide quick-cooking products which may be dried to low moisture content without hazard to the wholeness of the grainin'subsequent preparation and use. It is another object to provide a method of producing such quickcooking products in which the loss of nutritive solubles and solids yield is materially reduced. It is a still further object to provide a method of manufacturing quickcooking products which have the various advantages above recited; Other objects and attributes not all available in such quick-cooking products, and not achievable'by prior processes will be in part pointed out and in part become apparent as the specification proceeds.

It has been found that the above objects can be attainedby hydrating the raw grains by soaking with water, gelatinizing the starch by heating with steam, rinsing and then subjecting the tough gelatinized grains to a transient compression and then drying the grains. Products made according to the above process result in grains that are hard, dense and non-friable; that resist fraying, splitting and breaking during the hydration and cooking; and that are less sensitive to maceration when being cooked with a. quantity of water sufficient for maximum imbibition, and even when over-cooking occurs in soups. Furthermore, there is less loss of the products during preparation; and, the products are not subject to changes, predisposing them toward disintegration in the final preparation for the table, for example, when there is further drying to make them suitable for incorporation in dry soup mixes and the like. These products may be subjected to vigorous water boiling while in suspension as in soups with substantially less destruction to the wholeness and soundness of the grains than heretofore possible with other types of quick-cooking rice products, and this permits reheating of soups and ready use of leftoversf Similarly, in the kitchen cooking procedure of the grains,'fiuffing or stirring can be recommended since the grains are much less subject to' disintegration than the types heretofore known.

According to the present invention, milled polished rice in clean condition is soaked in Water below the gelatinization temperature until it has imbibed all or most of the moisture it needs for uniform gelatinization.-

Using water at room temperature or even colder, e.g. 65 F., the amount of moisture absorbed does not increase greatly with time after the first fifteen to thirty minutes. For instance, after washing and fifteen minutes of soaking, Patna, a long grain rice, will have a soak in a solution containing a small amount of citric.

acid. This tends to inhibit fermentive spoilage and also reduces the later tendency for the product to become.

rancid. Generally unlessrice is specially hard-brush milled or washed with detergents or solvents it may contain from 3% to 5% of very unstable rice oil. Accordingly it has often been found desirable to soak the rice in a 025% solution of citric acid. In one .test, the various washings 'to be indicated in the process de scribed herein reduced the original oil content of 0.5% m about .15% and the citric acid to a trace. As an indication of the small amount of residual citric acid, s'oup broth made from soup mix containing quickc'ooking rice not soaked with citric acid showed a pH of 6.44, whereas rice soaked with citric acid produced a broth with a pH of 6.41.

After the initial soaking process the rice is rinsedto wash away loose surface starch which is jelly-like and would tend to cement the grains together, causing.

caking and lumping during subsequent gelatinization.

The next step in the process is the gelatinization of the rice. This may be advantageously carried out in an autoclave in which the rice is preferably treated with relatively dry steam. Steam condensate or entrainment tends to cause local areas of oversoaked mushy rice grains which would be too soft for the subsequent mechanical compression. It was found that steaming to complete gelatinization can be carried out by pressure cooking the soaked rice in layers 1% inches thick at pounds per square inch gauge for 30 minutes. Thinner layers may be gelatinized more quickly, while thicker gelatinization. It should be, noted, however, that with higher pressure steam'there may be a tendency for thei rice to become slightly darkened in color, and it' is pre- I of the rice grains as they pass between the rolls.

ferred to avoid the higher pressures when whiteness of the grains is important. I

Completeness of gelatinization may be readily determined by observing when the individual grains have a rubbery character throughout, and there is an absence of White centers within the'grains.

At the end of the pressure cooking step it has been found that the individual grains tend to clump together in loose cake form. The gelatinized cake is discharged into wash water and agitated therein which operation detaches the adhering grains and conditions them for the compression treatment. 7 The rice grains at this stage are tough and plastic and rubber-like, and they can be handled'roughly without damage thereto.

It appears that there is considerable flexibility in the further processing depending upon various factors such as the end use for which the product is destined and the particular requirement of the apparatus being 'used. Thus the rice grains may be removed from this wash step immediately and fed to the compression step, or they may be permitted to soak for a considerable period of time. In the latter case the soaking permits the rice to imbibe more water and thereby imparts to it (after compression and drying) properties which give the final rice product the soft and fluffy texture desired for dishes prepared in the home. For example, rinsing for about one or two minutes at room temperature, results in a moisture content of about 43.5% in the Patna rice as it is fed to the pressure stage. Such rice has been found very suitable for further drying and incorporation in the dry mixes, and for general use in soups, but may be somewhat firm and. lacking in flufiiness for other general table uses and in puddings.

:Byfiletting the Patna rice soak following pressure cooking for a period of approximately 30 to 60 minutes in cool water, it may be made to imbibe water up to to total moisture content before being passed to the compression operation. The corresponding times and moisture contents for other varieties of rice vary depending upon average grain dimensions and other characteristics. For example, with Zenith, a medium grain rice, a 30 minute soak period before the pressure roller operation has been found to produce between 60% and total moisture. This rinsing or soaking step may take place in cool water although rinsing experi: mentally at elevated temperatures has also given good results.

;When this operation is completed the rice is fed through a compressing operation whichcompresses and momentarily flattens the individual grains of rice. Commercially this compression step has been performed by passing the grains between a pair of rolls; This step can be performed after a delay of as long as one and a half hours although no delay is necessary, and it is preferred that the delay not exceed approximately thirty minutes. Alimiting factor in the time delay is the loss of lubricity due to loss of surface moisture by evaporation orabsorption, which tends to cause a slight abrasion The freshly washed grains, with or without soaking are found to be in excellent condition for this compression roll operation and tend to flow individually from the hopper are squeezed as they pass through an aperture having a dimension which is illustratively one-fourth the minimum thickness of the moist rice grains. However, the rubber-like characteristic of the grains causes each of them to spring back immediately after passing through the aperture toward its original shape. After this spring back each grain is somewhat thinner, wider and longer than it was before passing to the aperture, but the grains are several times thicker than when passing through the aperture. While sulficient pressure is applied to comtrays at a rate of 500. feet per minute.

pact the grains somewhat, excessive pressure that would produce flaking or completely destroy the elasticity or resiliency of the gelatinized grain is to be avoided. It has been found that the gradual application of pressure to the individual grains permits greater compression than is possible with abrupt compression. The selection of wide diameter rolls makes possible the more gradual nipping of the grains and thereby the use of narrower aperture settings, which with narrow diameter rolls would tend to produce limp, battered-looking grains.

While it appears that this compressing may be accomplished in any suitable manner, it has been found that this operation may be accomplished advantageously by the use of a pair of opposed spaced rolls rotated so as to draw the grains in between the rolls on one side and discharge them out the other. Both of the rolls used are of the smooth type, and, although the term mill is commonly used to describe this type of apparatus, it is to-be understood no actual milling is intended or accomplished. Rolls of a diameter of 11% inches and a length of approximately 12 inches have been used satisfactorily for small-scale production. The rolls have been rotated at a variety of rates depending upon production.

requirements, but both rolls rotate at the same speed at all times to prevent attrition or flaking actions. The rolls have been spaced apart a distance of from .01 inch to .03 inch depending upon the type of rice being processed. With Patna and Rexora rice a spacing of .017 inch to .018 inch has been found to be satisfactory, and with Zenith rice a roll aperture of .021 inch is satisfactory. It has been found generally that the aperture between the rolls for rice should be of the order of onequarter to one-third the thickness of the moist pressurecooked grains. With the above equipment, an average capacity of 535 lbs. of pregelatinized Patna rice has been produced per hour when the rolls rotate at 40 r.p.m. This corresponds to 242 lbs. of rice solids per hour. Rates for barley through-put with the same rolls and conditions are at least as high.

As a result of this mechanical pressing between the rolls the rice grains become slightly less firm and some juices are pressed to the surfaces of the grains. This causes a slight mucilaginous condition at the surface which may cause some tendency toward agglomeration of the grains if drying is carried out directly. It has been found that the separation of the dried grains is facilitated if rice is given a final washing after the pressure stage.

After this final washing, the rice is dried in any .convenient manner, apparently without special limitations as to time and temperature. However, the excellent results referred to above were obtained by employing a cabinet dryer with the rice in trays to a density of 0.85 to 1.1 lbs. of rice solids per square foot, and airat a temperature of 175. F. was flowed horizontally over the A drying time of three to three and one-half hours was found to be entirely satisfactory; This time can be reduced considerably by providing thinner layers and/or higher drying temperatures-and/or air flow through the product. Under certain conditions drying temperatures up to 245 F. were used and the drying time was thirty minutes with no evident fundamental changes in rehydratability or product quality. However, in the same way it was found desirable to limit the pressure of thesteam in the pressure cooking step to preserve whiteness of the grain, it is preferable to avoid excessive temperatures in a prolonged drying step. 7

The finished rice product according to the present invention has an appearance somewhat longer and more slender than the original polished rice, and upon being hydrated it swells to form a white attractive long grain with little or no. suggestionto the unpracticed eye of its having been subjected to mechanical compression. The

grains are slightly reduced in, one dimension, but they do not approach a flaked condition such as in a flaked though pre-cooked, resembles very closely the original pearly polished rice from which it is derived. They do not appear to be opaque, puffed, porous or fragile. Upon close examination the dry grains of the rice product of the present invention; each grain exhibits thin parallel white lines transverse to the major axis of the grain; and microscopic examination discloses that these striations often are small vacuoles or =bubblelike voids.

The following table sets forth characteristics of the grains of a particular batch of rice processed according to the present invention and then reconstituted as might be done in the home, and compares the kitchen preparation of the quick-cooking product with that of the original rice.

Moisture Content, Percent Average Thickncss, Inch Average Stage of Process Length,

Inch

I. Original, Raw Polished Rice 13. Z 0. 066

5 II. After pressure cooking .5 0. 069 III. After washing, following cooking 43. 5 0. 070 IV. After compression through aperture of 0.017 inch 0.061 V. After drying the final Quick- Oooking Rice l 5 to 14 7 0.038 Kitchen Preparation Procedures:

- Cookingj raw'polished rice as used in stage I above 1 cup of rice was thoroughly washed, added to 1% cups water, brought to a boil over moderate flame, then cooked at low boil for 20 minutes until tender. Overall time about 30 minutes 67 B. Preparation of Quick-Cooking Rice produced as per stages I to V above- 1 cup rice added to 1 to 1% cups water, brought to a boil rapidly, removed from heat, covered and allowed to stand 10 minutes 68 1 Depending upon final use. 2 The rice grains are not uniformly circular at the minor axis. There is a slight natural flattening. These thickness measurements represent the lesser dimension.

prepared according to the present invention is cooked in the home, it provides consistently a pleasing appearance.

Extended cooking or even re-boiling of the rice which has been processed according to the present invention does not cause objectionable disintegration of the grains. The over-all percentage loss of the product during processing and preparation for the table is less with the present invention than with prior known processes, and this reduces the loss of solubles, i.e., minerals, vitamins and sugars, so that the final product has higher nutritional value. In addition to the advantages in the household use of the processed rice product, the process of the present invention affords yield economies in produc-.

tion that were not obtainable heretofore with other known processes for producing quick-cooking rice.

An advantage according to the present invention in,

gelatinization by immersion and boiling, the moisture product contains 55% moisture, it is necessary to remove one pound of moisture; when the wet product contains 75% moisture, it is necessary to remove 2.6 pounds of moisture. Similar comparisons may be made for other initial and final moisture contents, but in all cases the savings in connection with the present invention are substantial.

A further advantage of the present invention is an increased yield over processes heretofore known. With relatively small-scale operations using the present invention, yields have averaged 92% on a dry, solids basis. These relatively high yields are obtained due to the fact that the pressure cooking does not destroy the grain wholeness or dissolve solubles, as does immersion cooking in boiling water. In addition to the other factors,

the grains that may be damaged or checked during mill-.

ing and polishing or during soaking appear to be repaired or cemented during the pressure cooking process. The final dry rice product produced from Patna rice,

as described above, has an appearance which is remarkably like that of the original polished dry rice. The processed product has longer grains and the reduction in thickness is somewhat apparent. However, the coloring and general translucent appearance are substantiall the same.

It has been indicated above that the present invention contemplates the processing of other starch-containing products such as other cereals, and particularly barley. The processing of barley according to the present invention is carried on in a manner similar to the manner described above with respect to rice. The processing of barley involves departures from the above described processing of rice to compensate for the characteristics of barley which are different from those of rice. For example, barley requires longer soaking and cooking periods, but the dry processed product may be prepared for table use in substantially the same manner and time.

It has been found that barley known commercially as Acme 2/0 gives an excellent final product when processed in accordance with the present invention. It is our understanding that this particular barley'is produced from Campana rough barley which has been subjected to six pearling operations. Another commercial grade known as No. 3 Chicago barley has been processed and has pro-' longer if the grain size is exceptionally thick or if the' commercial operation makes further soaking desirable. When soaked for substantial periods, for example overnight, preferably the water should contain dilute citric acid as discussed above in connection with rice. The soaked barley is rinsedin freshwater to remove the surface material and loosened bran particles. Illustratively, the barley is then processed in the same manner as explained above for rice. With the equipment and processing conditions discussed above for rice, the Acme 2/0 barley was cooked 45 minutes with steam at pounds per square inch gauge, and was completely gelatinized. In this condition the individualbarley grains are rubbery and have uniformly translucent character. These individual grains may be squeezed with the fingers so thatmay be soaked for a period such as one hour prior to the mechanical compression operation. The aperture between the rolls for the mechanical compression is varied within reasonable limits depending upon the type of barley. However, for Acme 2/0 barley the aperture of 0.014 inch was very satisfactory. for kitchen preparations for puddings or other table use. At an aperture setting of 0.015 inch for Acme 2/0 barley the ultimate cooked product was appropriate for dry soup mixes. With No. 3 Chicago barley which has a large grain size, the aperture setting of 0.021 inch produced results comparable to the results obtained'with the 0.014 inch setting for Acme 2/0 barley.

During the processing of one particular specimen of barley as described above, the original raw polished barley contained 9.2% moisture. During the washing and soaking operation the moisture content rose to 42.5% and during gelatinization there was an additional rise to a moisture content of 44.5%. At this stage, after the product was rinsed and the mechanical compression applied, the moisture content was 52.9%. The product was then rinsed again and the moisture content was 55.8%. The aperture between the rolls of 0.014 inch was approximately one-eighth the thickness of the individual grains, -i.e., 0.114 inch, and the grains sprang bac to 0.099 inch thickness. In this case the barley was dried to a moisture content of 10%. The dried barley grains were found to have large central voids mostly open through at least one thin wall. Most of the grains had crevicesextending into and through the thicker walls. In this major respect, barley processed according to the present invention differs from similarly processed rice.

- When the barley is reconstituted and further cooked (i.e.,

prepared for table use), the voids and crevices appear .1 to permit the entry of water and promote rapid hydration. These voids do not' appear in the original raw grains, but they appear first after gelatinization.

In processing products in accordance with the present invention the gelatinization is completed during the steam "-cooking operation, but no free water is present and the product does not imbibe sufficient water to make it edible and palatable. Other known pre-cooking processes involve the absorption of substantially more water by the products prior to drying. As discussed above, the limited absorption of.water reduces the tendency for solubles to leach out. At the same time, with barley objectionable flavoring and coloring components of the crease bran are removed prior to the final cooking. Hence, the final barley product has most of the desirable constituents of the original barley, but the undesirable constituents have been largely removed. Barley prepared as above may be prepared for the table or. in soup in ten minutes; as indicated above, this is the maximum time which is generally accepted for the preparation of dry soup mixes.

While there are given above certain specific examples of this invention and its, application in practical use and also certain modifications and alternatives, it should be understood that these are not intended to be exhaustive or to be limiting of the invention. On the contrary, these illustrations and the explanations herein are given in order to acquaint others skilled in the art with this invention and the principles thereof and a suitable manner of its application in practicaluse, so that others skilled in the art maybe enabled to modify the invention and to adapt and apply it in numerous forms, each as may be best suited to the requirement of a particular use. It will be evident further that the various steps of the procedure may be performed with any known apparatus suitable to the particular operating conditions to enable adjustment of the times. and temperatures of soaking, cooking, compression, and similar factors according to the principles set forth above, to obtain the desired quick-cooking products. The method may also be applied to other desired varieties of cereals and other starch products without de- I claim: I

1. The method of processing raw grains of barley to form a quick-cOokingEprOduct which comprises, soaking said raw grains in water at a temperature less than that which would cause gelatinization to introduce into the grains substantially enough water for complete gelatinization of said grains, pressure cooking said soaked grains by subjecting them to steam at an elevated pressure until there is substantially complete gelatinization thereof, discharging the cooked grains into a body of water and agitating the cooked grains in said body of water to separate them into discrete grains, subjecting said discrete grains to transient compressive forces by passing them between a pair of rolls spaced apart a distance between about 0.01 and 0.03 inch, washing said grains to remove any exuded juices, and drying said grains to a moisture content between about and 14%.

2. The method of producing quick-cooking cereals which comprises, soaking raw grains of barley in water at a temperature below which gelatinization occurs for a period to produce absorption of substantially enough water for complete gelatinization, pressure cooking said grains with dry steam until complete gelatinization occurs,

discharging the pressure-cooked grains into a body of water and agitating them therein to lubricate them and separate them, passing the lubricated grains between a pairof rollers having a diameter of approximately twelve inche's'and spaced apart about 0.014 to 0,021 inch, and

drying said grains to a moisture content of approximate- 1y 5% to 14%.

pressure of about 15 pounds per square inch gauge for approximately forty-five minutes until there is substantially complete gelatinization thereof, discharging the cooked grains into a body of Water and agitating the cooked grains in said body of water to separate them into discrete grains, subjecting said discrete grains to transient compressive forces by passing them between a pair of rolls spaced apart a distance between about 0.01 and 0.03 inch, rinsing said grains and drying said grains to a moisture content of about 10%.

4. The method of processing barley to form a quickcooking product which comprises soaking raw barley grains in water at substantially room temperature until the grains attain a moisture content of approximately 42.5%, removing the grains from said soaking water, pressure cooking said grains at an elevated temperature for a period suflicient to produce substantially complete gelatinization of the grains, discharging said grains into a body of water and agitating them therein to separate the grains and lubricate their surfaces, momentarily compressing said grains to a thickness between about 0.014 r and 0.021 inch, and drying said grains to a moisture content of about 10%.

References Cited in the file of this patent UNITED STATES PATENTS Donelson Apr. 2, 1889 400,835 1,832,813 Luke Nov. 17, 1931 1,925,267 McKay Sept. 5, 1933 2,064,701 Stokkebye Dec. 15, 1936 2,438,939 Ozai-Durrani Apr. 6, 1948 2,733,147 Ozai-Durrani Jan. 31, 1956 FOREIGN PATENTS 657,691 Great Britain Sept. 26, 1951 

1. THE METHOD OF PROCESSING RAW GRAINS OF BARLEY TO FORM A QUICK-COOKING PRODUCT WHICH COMPRISES, SOAKING SAID RAW GRAINS IN WATER AT A TEMPERATURE LESS THAN THAT WHICH WOULD CAUSE GELATINIZATION TO INTRODUCE INTO THE GRAINS SUBSTANTIALLY ENOUGH WATER FOR COMPLETE GELATINIZATION OF SAID GRAINS, PRESSURE COOKING SAID SOAKED GRAINS BY SUBJECTING THEM TO STEAM AT AN ELEVATED PRESSURE UNTIL THERE IS SUBSTANTIALLY COMPLETE GELATINIZATION THEREOF, DISCHARGING THE COOKED GRAINS INTO A BODY OF WATER AND AGITATING THE COOKED GRAINS IN SAID BODY OF WATER TO SEPARATE THEM INTO DISCRETE GRAINS, SUBJECTING SAID DISCRETE GRAINS TO TRANSIENT COMPRESSIVE FORCES BY PASSING THEM BETWEEN A PAIR OF ROLLS SPACED APART A DISTANCE BETWEEN ABOUT 0.01 AND 0.03 INCH, WASHING SAID GRAINS TO REMOVE AND EXUDED JUICES, AND DRYING SAID GRAINS TO A MOISTURE CONTENT BETWEEN ABOUT 5% AND 14%. 